RU2634344C1 - Fuel burning method - Google Patents

Abstract

FIELD: energetics.

SUBSTANCE: invention can be used to flare solid fuel containing components of different reactivity (volatile). The fuel burning method consists in bringing the coal dust to the burners with primary air as the mixture of pulverized coal with the primary air, in the area of ignition of the burners due to the pyrolysis of coal dust from the mixture of pulverized coal with the primary air, primary gas with combustibles, gaseous components is produced, in the area of ignition the excess air is reduced by reducing its share in the fuel mixture or increasing the share of combustible components of the fuel in the fuel mixture, a flow of the primary gas mixture with the remaining portion of the solid fuel is performed, it is mixed with secondary air and post-combustion of the produced fuel mixture is performed in the furnace. In the ignition zone, the temperature threshold of carbon oxidation is reduced, for example, by electric action on the fuel mixture or by catalytic methods, slowing down the output of high-reaction fuel components, and by increasing the degree of gasification of carbon, its content in the resulting fuel mixture is reduced, while increasing the fraction of the gaseous components of the fuel in the resulting fuel mixture for afterburning it in the furnace.

EFFECT: invention makes it possible to increase the reactivity of the burnt fuel and to increase the efficiency of its combustion, to reduce the content of nitrogen oxides formed during the combustion of fuel.

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Description

The proposed technical solution relates to the field of processing solid fuels, which contains components with different reactivity, for example coal dust, and can be used to more stable combustion of fuel in the furnace and to suppress the formation of nitrogen oxides.

A known method of burning solid pulverized coal fuel, see the patent of the Russian Federation for invention No. 2199058, including the formation of air flows, a mixture of fuel and air, igniting the mixture in the furnace and burning it, moreover, at the initial stage, the air-fuel ratio corresponding to the coefficient of excess air relative to to volatile α _l > 1, and with respect to all fuel α _t = 0.2 ... 0.8. As the carbon fuel burns out, air is mixed with the mixture, and by the time the carbon burns out completely, the excess air reaches α _t ≥1.

Common features of the proposed technical solution and the above technical solution are:

- the formation of air flows, a mixture of fuel with air;

- setting the mixture on fire;

- burning the mixture at various excess air.

The disadvantages of this method is that the combustion of fuel at the initial stage occurs due to the combustion of the highly reactive component of the fuel, while heterogeneous reactions of carbon oxidation are blocked, as the less reactive component of the fuel. After combustion of the highly reactive component of the fuel, carbon fuel is burned, which requires, due to its low reactivity, additional measures to ensure the stability of the combustion process of the resulting fuel mixture, for example, a significant increase in excess air in the furnace (α _t ≥1.3), which leads to the formation of thermal nitrogen oxides and an increase in heat loss with flue gases.

A known method of burning fuel, described in the book [Zhukov MF, Karpenko EI, Peregudov B.C. etc. Plasma oil-free kindling of boilers and stabilization of the combustion of a pulverized coal torch. - Novosibirsk: Science. - 1995 .-- 304 s. - (Low-temperature plasma. T. 16), p. 86], in which a mixture of coal and air is supplied to the fuel thermal preparation chamber, the fuel mixture is heated and ignited using a plasma jet, part of the carbon is burned until the volatile components exit the coal and partial gasification of the coke residue, then the resulting fuel mixture and secondary air are fed into the boiler furnace and the fuel mixture is burned.

Common features of a similar and proposed technical solutions are:

- bring coal dust to the burners using primary air as a mixture of coal dust with primary air;

- produce partial combustion and gasification of coal dust before the release of volatile components of the fuel;

- in the ignition zone of the burners due to the pyrolysis of coal dust from a mixture of coal dust with primary air receive primary gas with combustible gaseous components;

- supply the resulting fuel mixture and mix it in the furnace with secondary air;

- burn the fuel mixture in the furnace.

The disadvantage of this method is that heating and ignition is carried out by low-temperature plasma, the temperature of the plasma jet exceeds 6000 ° C. This leads to an intensive process of release of volatile fuel components and their burning at the initial stage of fuel combustion. Due to the depletion of the oxygen content in the fuel mixture, the heterogeneous processes of carbon oxidation and gasification are slowed down. In addition, the high-temperature effect on the fuel mixture leads to the evaporation of the mineral components of the fuel with their further condensation on the particles of coal and on the surfaces of the burner devices, which leads to their slagging and prevents the oxidation of the carbon part of the fuel. As a result, almost the entire bulk of highly reactive fuel burns out before entering the furnace and the fuel mixture entering the furnace contains a coke residue of coal coated with a mineral film and a small part of unburned fuel in the gas phase, i.e. the reactivity of the fuel mixture is reduced compared to the original, which leads to a decrease in the efficiency of fuel combustion.

A similar technical solution is also known, see the patent of the Russian Federation for invention No. 2147708, which is selected as a prototype and which contains the following set of essential features:

- bring coal dust to the burners using primary air as a mixture of coal dust with primary air;

- in the ignition zone of the burners due to the pyrolysis of coal dust from a mixture of coal dust with primary air receive primary gas with combustible gaseous components;

- in the ignition zone, the excess air is reduced by reducing its share in the fuel mixture or increasing the proportion of combustible fuel components in the fuel mixture;

- in addition, part of the primary air in the mixture of coal dust with primary air is replaced by flue gas;

- supplying the resulting mixture of primary gas with the remainder of the solid fuel and mix it with secondary air;

- burn the fuel mixture in the furnace.

Common features of the proposed technical solution and prototype are:

- bring coal dust to the burners using primary air as a mixture of coal dust with primary air;

- in the ignition zone of the burners due to the pyrolysis of coal dust from a mixture of coal dust with primary air receive primary gas with combustible gaseous components;

- in the ignition zone, the excess air is reduced by reducing its share in the fuel mixture or increasing the proportion of combustible fuel components in the fuel mixture;

- supply the resulting mixture of primary gas with the remaining part of the solid fuel to the furnace and mix it with secondary air;

- burn the fuel mixture in the furnace.

The technical result, which cannot be achieved by any of the similar technical solutions described above, consists in a higher degree of carbon gasification, an increase in the proportion of fuel components in the gas phase due to carbon gasification, and, as a consequence, in a decrease in the proportion of carbon in the fuel mixture, burned in the furnace.

The reason for the impossibility of achieving the above technical result is that in the process of pyrolysis of coal dust, first of all, the volatile components contained in coal are released, which have a higher reactivity and block carbon oxidation reactions upon further combustion. When the coke residue is afterburned, in order to ensure the stability of the combustion of the mixture of coke particles and air, an increased content of the oxidizing agent is required, which leads to generation of the formation of nitrogen oxides in the furnace and an increase in heat loss with flue gases.

Given the characterization and analysis of known technical solutions, we can conclude that the task of creating methods of burning fuel with higher efficiency of burning fuel and suppressing the formation of nitrogen oxides during its combustion is relevant today.

The technical result indicated above is achieved by bringing coal dust to the burners using primary air as a mixture of coal dust with primary air, in the ignition zone of the burners, due to the pyrolysis of coal dust from the mixture of coal dust with primary air, primary gas with combustible gases is obtained the components in the ignition zone reduce the excess air by reducing its share in the fuel mixture or by increasing the proportion of combustible fuel components in the fuel mixture, the resulting mixture is fed primarily gas with the remaining part of the solid fuel, mix it with secondary air and burn the resulting fuel mixture in the furnace, and in the ignition zone lower the temperature threshold of carbon oxidation, for example, due to the electrical effect on the fuel mixture, known and described in the literature [D. BUT. Yagodnikov A.V. Voronetsky. The influence of an external electric field on the characteristics of the ignition and combustion process. Journal, “Physics of Combustion and Explosion,” No. 3, 1994, p. 3-12], or by widely known catalytic methods, they slow down the output of highly reactive fuel components and, by increasing the degree of gasification of the carbon part of the fuel, reduce its content in the resulting fuel mixture, while increasing the proportion of gaseous fuel components in the fuel mixture burned in the furnace.

Reducing the temperature of carbon oxidation by known methods (for example, by applying electric fields to the fuel mixture, using catalysts) slows down the process of pyrolysis of coal and active gasification of carbon, while a highly reactive fuel mixture of volatile carbon, carbon monoxide, and coke residue and hydrocarbon compounds formed from water contained in the fuel, which ensures the stability of combustion of gasified fuel in the furnace and an excess of oxidant close to the stoichiometric value. The decrease in the formation of nitrogen oxides at the initial stage of ignition occurs due to the combustion of fuel at low excess air at values of α _t = 0.2 ... 0.5, the afterburning of the fuel mixture in the furnace is carried out during slow mixture formation, which also helps to reduce the formation of nitrogen oxides. The high reactivity of the fuel mixture with a high content of combustible components in the gas phase and a low content of coke residue ensures stability and a high degree of fuel burnout.

In this, the achievement of the above result is manifested.

The technical essence of the proposed method of burning fuel is as follows:

- bring coal dust to the burners using primary air as a mixture of coal dust with primary air;

- in the ignition zone of the burners due to the pyrolysis of coal dust from a mixture of coal dust with primary air receive primary gas with combustible gaseous components;

- in the ignition zone, the excess air is reduced by reducing its share in the fuel mixture or increasing the proportion of combustible fuel components in the fuel mixture;

- ensure that the process of gasification of carbon to the release of volatile components of the fuel by reducing the temperature of the heterogeneous chemical reactions, for example, by electrical or catalytic effects on the fuel mixture;

- supplying the resulting mixture of primary gas with the remainder of the solid fuel and mix it with secondary air;

- burn the fuel mixture in the furnace.

A decrease in the ignition temperature of carbon slows down the pyrolysis of the fuel and its gasification at the stage of its ignition. As a result of this, the proportion of oxygen spent on the oxidation of the volatile components of the fuel is reduced due to the slowing down of their exit from the fuel, which ultimately ensures high reactivity of the fuel mixture when it is burned in the furnace. Thus, a more stable fuel combustion process is ensured with excess air close to the stoichiometric value.

The proposed method of burning fuel can be used to burn other types of fuel, for example industrial combustible waste containing fuel components with different reactivity.

Claims (1)

The method of burning fuel, which consists in bringing coal dust to the burners using primary air as a mixture of coal dust with primary air, in the ignition zone of the burners due to the pyrolysis of coal dust from the mixture of coal dust with primary air receive primary gas with combustible gaseous components , in the ignition zone, the excess air is reduced due to a decrease in its share in the fuel mixture or an increase in the proportion of combustible fuel components in the fuel mixture, the resulting mixture of primary gas is supplied with the remaining part of the solid fuel, mix it with secondary air and burn the resulting fuel mixture in the furnace, characterized in that in the ignition zone the temperature threshold of carbon oxidation is lowered, the yield of highly reactive fuel components is slowed down and its content in the resulting carbon is increased fuel mixture, while increasing the proportion of gaseous fuel components in the resulting fuel mixture for afterburning it in the furnace.